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Informationen zum Autor Dr Joseph Katz is Professor of Aerospace Engineering and Engineering Mechanics at San Diego State University. His rich and diverse academic and engineering background covers typical aerospace and automotive disciplines such as computational and experimental aerodynamics, vehicle dynamics, race car aerodynamics, and engine cooling. As a race car designer for the past 25 years, Dr Katz has participated in a large number of projects involving open wheel (F1 and Indy), prototype (IMSA), hill-climb, and NASCAR. His fluid mechanics research interests include unsteady aerodynamics and incompressible flow with a strong emphasis on developing numerical techniques. Prior to his academic position, he spent four years at the NASA Ames research center full-scale wind tunnel facility. For his work in developing the PMARC computational tool, he and his team received the 1997 NASA Space Act Award. In recent years, he has been active in the aerodynamic development of unmanned aerial vehicles (Global Hawk, E-Hunter), which now operate successfully throughout the world. Dr Katz received numerous awards for being the most influential teacher and outstanding educator (AIAA), and he is the author of several books and more than 100 other publications. His book on race car aerodynamics can be found on the desks of most race car designers around the world. Klappentext Familiarises students with the basic elements of fluid mechanics and provides a comprehensive foundation for more advanced courses. Zusammenfassung Designed as a first course on this subject! this book introduces the principles of fluid mechanics! and at the same time it provides sufficient analytical background for more specific courses in this field. The reader will understand the basic principles and have the ability to use these skills for engineering design. Inhaltsverzeichnis 1. Basic concepts and fluid properties; 2. The fluid dynamic equation; 3. Fluid statics; 4. Introduction to fluid in motion - one-dimensional (frictionless) flow; 5. Viscous incompressible flow: 'exact solutions'; 6. Dimension analysis, and high Reynolds number flows; 7. The laminar boundary layer; 8. High Reynolds number flow over bodies (incompressible); 9. Introduction to computational fluid mechanics (CFD); 10. Elements of inviscid compressible flow; 11. Fluid machinery....
